Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I have big problem to parallelize BLAKE using OMP. They sugested in specification that it is possible to parallelize "column step" and "diagonal step". I try to do this but the results are opposite that I expected (10 times slower than one-threaded). I need a little help from more experienced users of OMP, because now I have no idea how to parallelize this loop :(

Update:

I know that authors of BLAKE published BLAKE2, which is improved (faster) version of BLAKE, but it has different implemention (tree-hashing) than BLAKE and this is quite hard to understand for me. My task is to do compare of one-threaded and multi-threaded implementation using OMP. So I try to do this on implementation that I understand. I am not expert of OMP, I want to make BLAKE multi-threaded in the easiest way possible. I must do proper implementation with OMP even if the performance may not be better. (Sorry for my english, I hope that you understand me) This is part of my code:

 #pragma omp parallel shared(n)
  {
 for(round=0; round<n; ++round) 
 {
/* column step, I want to run this 4 G32 functions in parallel, but don't know,
   that is proper approach to this problem */
        #pragma omp critical 
     G32( 0, 4, 8,12, 0);
        #pragma omp critical 
     G32( 1, 5, 9,13, 1);
        #pragma omp critical 
     G32( 2, 6,10,14, 2);
        #pragma omp critical 
     G32( 3, 7,11,15, 3);    

/* diagonal step, and same here */
        #pragma omp critical 
     G32( 0, 5,10,15, 4);
        #pragma omp critical 
     G32( 1, 6,11,12, 5);
        #pragma omp critical 
     G32( 2, 7, 8,13, 6);
        #pragma omp critical 
     G32( 3, 4, 9,14, 7);
}
}

And this is G32 function:

#define G32(a,b,c,d,i)\
 do { \
v[a] = ADD32(v[a],v[b])+XOR32(m[sigma[round][2*i]], c32[sigma[round][2*i+1]]);\
v[d] = ROT32(XOR32(v[d],v[a]),16);\
v[c] = ADD32(v[c],v[d]);\
v[b] = ROT32(XOR32(v[b],v[c]),12);\
v[a] = ADD32(v[a],v[b])+XOR32(m[sigma[round][2*i+1]], c32[sigma[round][2*i]]);\
v[d] = ROT32(XOR32(v[d],v[a]), 8);\
v[c] = ADD32(v[c],v[d]);\
v[b] = ROT32(XOR32(v[b],v[c]), 7);\
} while (0)
share|improve this question
2  
What did your OMP look like? –  Oliver Charlesworth Jan 10 '13 at 15:27
1  
That claim is about SIMD parallelization. If you want to use multiple threads, consider Blake2*p which allows compression function calls in parallel, which works much better with threads. –  CodesInChaos Jan 10 '13 at 16:00
    
The BLAKE2*p variants are quite simple. You divide the message into blocks, and distribute those blocks among 4 threads, and finally you hash the output of those 4 partial hashes again to get the final hash. –  CodesInChaos Jan 11 '13 at 16:44
    
But is the hash the same like non-divided message? –  user1967089 Jan 14 '13 at 6:33

1 Answer 1

I think the kind of parallelization they had in mind was exploiting SIMD instrctions under modern CPUs. The problem with OMP-style parallelization in this case is two-fold:

  • The G32 tasks are too "small" or "short" so that the overhead with respect to starting the tasks in different threads and joining is too great in comparison.
  • False Sharing: The memory locations that are read and modified in the tasks are too close together. They probably share a cache line. This is bad because this requires special synchronization and makes read/writes from different threads very slow.
share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.